Nevertheless, her team went on to use their ISS muscle-on-chip samples to conduct proof-of-concept drug screening tests. Drugs they tested included those used to treat sarcopenia, among other conditions.
Space drugs
“One of the drugs we tested was the [protein] IGF 1, which is a growth factor naturally found in the body in different tissues, especially in muscles. When there is an injury, IGF 1 activates within a body to initiate muscle regeneration. Also, IGF 1 tend to be declined in aging muscles,” said Huang. The second drug tested was 15-PGDH-i, a relatively new inhibitor of enzymes that hinder the process of muscle regeneration. Used on the muscles-on-chip on the ISS, the drugs partially reduced some of the microgravity-related effects.
“One of the limitations of this work was that on the ISS, the microgravity is also accompanied by other factors, such as ionizing radiation, and it is hard to dissociate one from the other,” said Huang. It’s still unclear if the effects observed in the ISS samples were there due to radiation, the lack of gravity, both, or some additional factor. Huang’s team plans to do similar experiments on Earth in simulated microgravity conditions. “With some of the specialized equipment we recently acquired, it is possible to look at just the effects of microgravity,” Huang said. Those experiments are aimed at testing a wider range of drugs.
“The reason we do this drug screening is to develop drugs that could either be taken preemptively or during the flight to counteract muscle atrophy. It would probably be more feasible, lighter, and cheaper than doing artificial gravity concepts,” Huang said. The most promising candidate drugs selected in these ground experiments will be tested on Huang’s muscle-on-chip systems onboard the ISS in 2025.
Stem Cell Reports, 2024. DOI: 10.1016/j.stemcr.2024.06.010
